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Maps, Maidens and Molecules Transcript Maps, Maidens and Molecules Transcript Date: Wednesday, 16 October 2002 - 11:00PM Maps, Maidens and Molecules: The world of Victorian combinatorics by Robin Wilson This talk on Victorian combinatorics combines my interests in the history of British mathematics particularly during the Victorian period - and in combinatorics. The word 'Victorian' is straightforward: most of the events I'll be talking about occurred in Britain in the period of Queen Victoria's reign. But what about 'combinatorics'? The word is clearly related to 'combinations', and it refers to the area of mathematics concerned with combining, arranging and counting various things, as you'll see. Much of the development of combinatorics in the nineteenth century took place in Victorian Britain, often by eccentric amateur mathematicians (frequently, clergymen, lawyers and military gentlemen) who found such problems appealing; for example, in Thomas Pynchon's book Gravity's Rainbow, there's an elderly character called Brigadier Pudding, of whom it is said: he was, like many military gentlemen of his generation, fascinated by combinatorial mathematics. For today, I've chosen four typical (but varied) topics to illustrate Victorian combinatorics, and here are some of the people you'll be getting to know in the next hour. Incidentally, this talk can be taken on various levels, so although I'll need to get technical from time to time, don't worry if you don't follow all the mathematical details; just hang on and wait for the more historical parts. I've called the first topic 'triple systems', and I'd like to start by introducing you to the annual Lady's and Gentleman's Diary: designed principally for the amusement and instruction of students in mathematics, comprising many useful and entertaining particulars, interesting to all persons engaged in that delightful pursuit. In 1844, its editor, the Revd. Wesley Woolhouse, himself a keen amateur mathematician, presented Prize Question No. 1733 for his readers to solve: Determine the number of combinations that can be made out of n symbols, p symbols in each; with this limitation, that no combination of q symbols, which may appear in any one of them shall be repeated in any other. Don't worry if you don't understand this - many of the attempted solutions showed that its solvers didn't understand it either. In fact, no-one managed to produce a satisfactory answer, and so in 1846 Wesley Woolhouse made it simpler by choosing p = 3 and q = 2. The problem then becomes: How many triads can be made out of n symbols, so that no pair of symbols shall be comprised more than once amongst them? As you can see, it's a problem about arranging things: we take a number of symbols and we're asked to arrange them into 'triads', or 'triples', in such a way that a particular condition is satisfied. Here's an example. We've taken our 7 symbols to be the numbers 1 - 7, and arranged them vertically into triples, as shown below: 1234567 2345671 4567123 The condition that has to be satisfied is that no pair of numbers may occur together more than once - here, and from now on, each pair appears exactly once. For example, the numbers 2 and 3 appear together in the second triple, while the numbers 3 and 7 appear together in the final triple, and the same is true for any two of the numbers that you choose. Such an arrangement of numbers is now usually called a Steiner triple system, after the Swiss mathematician Jakob Steiner, but Steiner did nothing on them and the credit should rightly go to a Lancashire clergyman, the Revd. Thomas Penyngton Kirkman, who made substantial contributions to the subject, as you'll see. Kirkman was the rector of the tiny parish of Croft-with-Southworth, near Warrington. His parochial duties were not demanding, and left him a lot of time to have seven children and do a lot of mathematics, becoming a Fellow of the Royal Society in the process. Here are two triple systems - the one we had before for n = 7, with seven triples, and one for n = 9, with twelve triples. Again, note that any pair of numbers appears in exactly one triple - for example, in the second system, the pair 3 and 8 appear together in the eighth triple. 1234567 2345671 4567123 111122233347 245645645658 379898787969 Such triple systems are used in agriculture, in the design of experiments. Suppose that you wish to compare seven varieties of wheat. If your fields are not large enough for you to plant all seven types of wheat in each field, you can plant varieties 1, 2 and 4 in the first field, varieties 2, 3 and 5 in the second, and so on. With the above arrangement, you can directly compare each pair of varieties in one of the seven fields. Notice, by the way, that this first system is easy to construct, since from the first triple, consisting of 1, 2 and 4, you can then obtain each successive triple by adding 1 to each number, replacing 7 by 1 whenever you need to; so, once you've found your starting triple, the rest follows. Such systems are called cyclic systems, and we'll see them again later; they've even been used in music theory, where each triple represents a chord of three notes and each chord after the first is obtained from the previous one by transposition. When do triple systems exist? They certainly exist when n is 7 or 9, but for which other values? In a ground-breaking paper of 1847, Kirkman showed, by a simple counting argument, that triple systems can occur only when n, the total number of symbols, is one of the numbers in the sequence 7, 9, 13, 15, 19, 21, 25, . - these numbers are all 1 or 3 more than a multiple of 6; indeed, you can see that the total number n must be odd because the number 1 appears with all the other numbers in pairs. Kirkman also showed - and this was much more difficult - that for each such number one can actually construct such a triple system, and he gave an explicit construction for doing so. Before I introduce the 'maidens' in the title of this talk, I'd like to look again at the system with n = 9. 147|123|123|123 258|456|645|564 369|789|897|978 Here I've rearranged the twelve triples in such a way that the system splits into four parts with all the numbers from 1 to 9 appearing in each part. In the context of comparing varieties of wheat, you can think of each part as representing a season: in the first season, you plant three fields with varieties 1, 2 and 3 for the first; 4, 5 and 6 for the second; and 7, 8 and 9 for the third; in the next season you plant them with varieties 1, 4 and 7; 2, 5 and 8; 3, 6 and 9; and so on for the remaining two seasons. After four seasons, you will have succeeded in comparing each pair of varieties exactly once. Such a division into seasons can happen only when n is divisible by 3, which means that n must be 3 more than a multiple of 6. This includes the case n = 9, and also n = 15, as we now see. One of the entertaining features of the Lady's and Gentleman's Diary was that it always contained a number of queries sent by the readers, and 1850 was no exception. In that year, there were queries by Mr Lugg on the origin of April Fools' Day, by the Revd. Hope on the three sons of Noah, by Mr Herdson on the saltiness of the sea, and finally a query by the Revd. Thomas Pennington Kirkman: Fifteen young ladies in a school walk out three abreast for seven days in succession: it is required to arrange them daily, so that no two shall walk twice abreast. If there had been only 9 young ladies, we could have used the system above, with the four seasons now corresponding to four days: on the first day, 1 walks with 2 and 3, 4 walks with 5 and 6, and 7 walks with 8 and 9; on the second day, 1 walks with 4 and 7, and so on - and no two young ladies walk together more than once. The problem for 15 young ladies is now known as the Kirkman schoolgirls problem: here's a solution of it. (OHP) Monday: 1-2-3; 4-5-6; 7-8-9; 10-11-12; 13-14-15 Tuesday: 1-4-7; 2-5-8; 3-12-15; 6-10-14; 9-11-13 Wednesday:1-10-13; 2-11-14; 3-6-9; 4-8- 12; 5-7-15 Thursday:1-5-11; 2-6-12; 3-7-13; 4-9-14; 8-10-15 Friday:1-8-14; 2-9-15; 3-4-10; 6-7-11; 5-12-13 Saturday:1-6-15; 2-4-13; 3-8-11; 5-9-10; 7-12-14 Sunday:1-9-12; 2-7-10; 3-5-14; 6-8-13; 4-11-15 Notice that, as before, any two schoolgirls walk together exactly once; for example, schoolgirls 3 and 10 walk together on Friday. This question was more successful than the one in the 1844 Lady's and Gentleman's Diary. Here are the solutions that appeared in the 1851 Diary: one by Kirkman himself, and one obtained independently by Mr Bills of Newark, Mr Jones of Chester, Mr Wainman of Leeds, and Mr Levy of Hungerford; how they all came up with exactly the same solution, I have no idea.
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